H1_H4_letter
Offices and schools
Utilities / Renewable energy
Storage Battery System Using Lithium‐ion Batteries
Worldwide Expansion of Storage Battery System Applications
Commercial Buildings
Residential
The Smart Energy System combines our technologies for energy creation (photovoltaic modules), energy storage (rechargeable batteries), and energy saving (efficient energy usage). The system stores electricity generated by photovoltaic modules as well as low-cost late-night power in lithium-ion batteries. By controlling electrical usage in the most efficient way possible, the Smart Energy System reduces facility CO2 emissions and power consumption.
【North America (USA, Canada)】
【Europe】
【Other area】
SANYO Component Europe GmbH Solar and Smart Energy Division
Mobile Energy Business Division
International Sales & Marketing Headquarters
email:
[email protected]
Smart Energy Systems Department
email:
[email protected]
email:
[email protected]
The contents of this catalogue are current as of June 2012.
P01_02_letter
Smart Energy Storage System: A scalable power storage system for multiple energy storage applications Based on Panasonic’s unique technology development abilities, production technology, and global supply chain, the company has achieved and maintained a major share of the global lithium-ion battery market. Offering an extensive lineup of lithium-ion batteries ranging from small applications such as consumer batteries for laptop computers, to larger applications such as the batteries used in environmental vehicles, Panasonic is a leading company in battery technology for various applications. In addition, Panasonic is a leader in the development and production of photovoltaic modules. Now, based on this foundation, Panasonic has entered the market for Smart Energy Storage Systems, adding a fourth key product area to already established presence in photovoltaic modules, rechargeable batteries, and batteries for electric and hybrid electric vehicles. Looking forward to future expansion in the renewable energy storage market, Panasonic will use its leading Smart Energy Storage System to maximize customer satisfaction with “coordination and integration” technologies actively tailored to meet customer needs.
To realize a low-carbon society of the future As utility companies begin the large-scale introduction of renewable energy to the grid, Smart Energy Storage Systems will become a key component. This is because renewable energy sources can cause instability with fluctuations in the power they produce. Acting as a stabilizer for renewable energy, the Smart Energy Storage Systems will serve as an energy storage source and play a critical role in the low-carbon society of the future.
CO2 Emissions Reduction System Stabilization
Large-Scale Power Plants
Hydro Power Plant
Power customers (from commercial to residential users) V2G
(Vehicle to Grid) 24 hour
Power Transmission Network
Local Generation and Consumption of Energy
■ Various applications for rechargeable batteries
Environmental Vehicles
Thermal Power Plant
Small-Scale Power Plant
Driving application Information
Large-Scale Battery System for Power Storage
Environmental Vehicle Batteries
Scooters / Bicycles
24 hour
store
Communities
New Battery Pack
store
UPS
Residential Use
Industrial Use
Solar Power generation
Comprised of storage batteries and control units to manage charging and discharging, Panasonic’s Smart Energy Storage System is suitable for various applications (e.g. Residential Energy Storage, Community Energy Storage, Utility scale ancillary services, etc.). Through the unique control method and know-how of managing energy storage, the system can control systems with over 1,000 storage batteries as part of a 1-MWh or greater system.
Peak Cut / Peak Shift / Energy Shift
Stationary Type
Buildings / Stores / Factories
Wind Power Generation
Scalable solutions for various needs in the utility grid
Cylindrical 18650-Type Batteries
Consumer Devices
Battery Power (kW)
Power
Nuclear Power Plant
Home and Business
System Stabilization
Community
Grid Support
Utility Use
Total Battery Capacity (kWh)
24 hour
store
Homes
Small Stores
■ Panasonic’s Energy Business
Photovoltaic Modules
Rechargeable Batteries
Rechargeable Batteries for Environmental Vehicles
Large-Scale Battery Systems for Stationary Applications
HIT® Photovoltaic Modules
Conventional Rechargeable Batteries
Batteries for HEVs / PHEVs / EVs
System Development
Schools / Medium-Size Stores Community Centers (Fire Stations)
Buildings
Factories
Solar / Wind Power
Power Plants
Battery Management System
Modules with global top-level conversion efficiency. Unique technology offers optimum power generation in smaller spaces as well as better production in hotter environments.
Batteries with high performance and reliability have earned the confidence of customers around the world. Panasonic has a leading share of the global market.
Panasonic is developing and e x p anding t he bus ine s s f or rechargeable batteries for electric and hybrid electric vehicles.
●Battery Protection Unit (BPU) and Battery Protection Module (BPM) for small scale systems ●Battery Management Unit (BMU) for mid to large scale systems ●Standard battery modules for energy storage
Panasonic's modules and equipments are indicated in blue.
4.0 kWh
6.8kWh
27 kWh
100 kWh
1 MWh
"HIT" is a registered trademark of SANYO Electric Co., Ltd. The name "HIT" comes from "Heterojunction with intrinsic Thin-layer" which is an original technology of SANYO Electric Co., Ltd.
1
Storage Battery System
Storage Battery System
2
P03_04_GridSupport_letter
Stabilizing Power from Renewable Energy Sources
Solutions for the large-scale introduction of renewable energy! ■ ■ ■
Amount of installed Solar (World)
Fluctuating power and severe output changes from wind and solar energy sources can be stabilized with energy storage, providing high quality power to the grid.
Amount of installed Wind (World) 1,000
340 GW 500 200
Solutions for severe power fluctuations Solutions for frequency regulation Solutions for peak-power demand
159 GW
20 GW
0
2009
0
2020
2009 : [TRENDS IN PHOTOVOLTAIC APPLICATIONS Survey report of selected IEA countries between 1992 and 2009] (IEA PVPS) 2020 : [JPEA PV Outlook 2030] (JPEA)
Solar power output
Power
1-MW System
2009
2020
2009 : [GLOBAL WIND 2009 REPORT] (GWEC) 2020 : [GLOBAL Wind Energy Outlook 2010] (GWEC)
Solar Power + Storage Battery System
Employing Smart Energy Storage System for utility scale
832 GW
Wind Power + Storage Battery System Wind power output Power
Grid Support
Charging
Smoothed Output
▲
Discharging
Power fluctuations caused by renewable energy Discharging Time
24 hour
▲
Power stabilization using Smart Energy Storage System
Grid
24 hour
store
Instant Power Fluctuation Control (Frequency Control) Utilizing the high-rate characteristics of lithium-ion batteries When demand rises, the Smart Energy Storage System instantly begins discharging, and frequency drop is controlled. Also when demand declines, frequency rise is controlled by charging.
Discharge from Storage
Frequency with Storage
Demand
power
store
Grid Frequency
Grid
Time
Frequency without Storage Charge to Storage Time
Grid-Scale Battery System Example
Storage Battery System
Time
Project SIESTORAGE (Siemens Energy Storage)
Panasonic’s 500 kWh battery system, consisting of 280 battery modules and battery management systems, is being used in field test as an integral part of Siemens’s new SIESTORAGE module energy storage container. The SIESTORAGE is directly connected to the medium voltage grid in South Europe.
3
Power Supply
Storage Battery Capacity/Output
500kWh/1MW
Application
This storage system serves as a variety of applications such as Smoothing the natural fluctuations of solar and wind power to stabilize power supply and prevent power outage.
Storage Battery System
4
P05_06_community_letter
Community Grid
Community Off-Grid Solutions to reduce the use of natural gas or other fueled generators for Micro Grids!
Solutions to minimize capital investment by using distributed energy storage on the grid. Solutions for severe power fluctuations ■ Solutions to stabilize distribution system’s voltage Employing Distributed Energy Storage System for a power grid(Community energy storage) ■
27-kWh System
27-kWh System
Employing Smart Energy Storage System for a power grid (Community energy storage)
Employing Smart Energy Storage System in combination with natural gas or other fueled generators Natural gas or other fueled generator output used to meet fluctuations in power demand
By introducing energy storage, natural gas or other fueled generators can operate at a constant rate, minimizing the fuel usage and even reducing the number of generators needed.
Load
Grid
Load
Inverter
Generator ▲Community energy storage
Backup Power Source during Outages
Use fluctuating power from wind and solar sources to charge storage batteries, effectively stabilizing power to the grid.
Power generated at night charges the Smart Energy Storage System, and is discharged during the daytime, shifting the peak demand and stabilizing the grid.
Power from the battery storage system can also serve as a backup power source in the event of a power outage.
Power
Solar power output
Charging
Discharging Smoothed Load
Demand Shift
Generator with Battery Management & Load Profile Load averaging is achieved by adding Smart Energy Storage System, reducing diesel fuel consumption. This can realize reduction of the number of natural gas or other fueled generators.
Original Load Output
Solar Power + Storage Battery System
Generator
Discharge
Generator #5
Power
Peak Demand Shift
Output
Stable Power Output
Charge
Generator #4 Generator #3
Discharge Discharging
Time
Time
Medium-Scale Power System Example
Generator #2
Energy usage Generator operating capacity
Charging Time
Generator #1 Time
University (USA) SES Controller
Panasonic is conducting a demonstration project with a University in the United States, where we combine the Smart Energy Storage System with a technology to forecast the output of solar generation. This demonstration project is aiming to contribute to the stable and reliable supply of electricity in an area with high level renewable penetration.
Power Conditioner
CHARGE
DISCHARGE Inverter
Lights
Storage Battery Capacity/Output
32 kWh / 7.2 kW
Photovoltaic Modules
30 kW
Battery Management Unit Air conditioners
Photovoltaic Module
Application
Charges the electricity generated by PVs, and uses it for peak load cut and backup power supply. Jointly demonstrating a system to forecast solar power output with a University.
Power outlet Commercial Power (AC)
Lib unit x 20sets
Lithium-ion Battery System
5
Storage Battery System
Facilities
In operation since June 2011
Storage Battery System
6
P07_08_small_letter
Homes and Small Stores
Industrial/ Commercial Reduces electricity bills by reducing contracted power (peak shifting) ■ Can be utilized as UPS function ■ Also can act as a valuable asset for Energy Arbitrage/Demand response and other applications ■
■ ■ ■
Reduces power bills through self-consumption of photovoltaic electricity Contributes to the reduction of CO2 emissions Serves as an emergency power source in the event of a disaster
27-kWh System
4.0/ 6.8-kWh System
Employing Smart Energy Storage System in a home or small store
Homestation DC
DC DC
AC DC DC
store
iEMCpro
Employing Smart Energy Storage System for buildings, factories, and schools
House Cabinet
VNB (Gridowner)
PV Module AC Load (Home)
Lithium-ion Battery System
Backup Power Source during Outages
Power stored during off-peak, late-night hours in the battery storage system is discharged during daytime peak demand, effectively shifting the peak demand.
Power from the storage system can be used as a backup power source in the event of a power outage.
Shifting peak demand usage by combining photovoltaic modules and Smart Energy Storage System; maximizing consumption of photovoltaic module power (Conventional PV)
Original Load Discharging Smoothed Load
Demand Shift
PV generation PV generation〈feed to grid〉 LOAD Consumption electricity bill
Before Output
Output
Peak Demand Shift
feed to grid Discharge
After
(PV Plus Battery)
PV charges to Battery feed to grid Battery discharges to load
PV generation〈charge〉 PV generation PV generation〈feed to grid〉 Battery discharges to load LOAD Consumption electricity bill
Charging Time
Facility UPS When there is a power outage, the lithium-ion battery storage system can operate as a UPS system to bridge the operation of critical systems until the power returns or a backup generator starts. Installation example: TV and radio stations operating during severe weather conditions Fire and rescue dispatch systems
Time
0
6
12
18
23
Residential Storage Battery System Example
Time
0
6
12
18
23
Time
Adoption for Home System (Germany)
Storage Battery Capacity
4.05kWh
Photovoltaic Modules
4.6 kW
Application
Storage batteries are used to maximize the use of solar power, which leads to higher self consumption. The stored energy is used during the period without solar radiation.
Under operation
7
Storage Battery System
Storage Battery System
8
P09_10_systemspec_letter
Configuration of Smart Energy Storage System 24 hour
Panasonic's Kasai Green Energy Park (Japan) In the power storage building at the Kasai Green Energy Park, there are more than 800 standard battery modules, each with an output of 1.6kWh. Panasonic has developed one of the world's top level power systems with the Lithium Mega Storage System at the site. Efficiently controlled energy generated from photovoltaic modules, as well as energy provided through off-peak, late-night grid power stored in these storage batteries, is utilized through optimal energy management.
store
Battery Management Unit (BMU) Power Conditioner
Battery Management System This component controls the charging and discharging of the storage batteries. Comprised of standard modules for power storage and a battery management controller, this component can manage multiple component batteries so that they can be used as if they were a single battery.
1.5 MWh / 288 kW
Photovoltaic Modules
1 MW
Application
Peak shaving: Store late-night power from the grid and surplus solar power for daytime use in the Kasai Green Energy Park
Standard Battery Module for Energy Storage
Contains 312 Battery cells
(DCB102U/104E) The standard battery module is a freely scalable building block containing 312 cylindrical 18650-type lithium-ion battery cells (18 mm diameter, 65 mm length) often used in laptop computers and power tools. By using proven battery technology, we are able to realize the highest level of safety and quality.
Cylindrical 18650-Type Lithium-ion Battery Cell
In operation since October 2010
Accomplishment of average 17% peak shaving in July, 2011
Technology Features Small Scale System
Storage Battery Capacity/Output
High-Rate Unit
High-Rate System
●Average peak shaving rate is 17% in Peak hour of electricity demand (13:00 ∼ 16:00) ●Annual utility charge reduction effect (preliminary calculation) is about 3.5 million yen
BMU BMU BPU/BPM Charge
Charge
Charge
Peak cut ratio for each day
Discharge
Discharge
Discharge
Storage Batteries
Max. 5 modules in parallel
Battery module
DCB-102U Simple system for residential storage system
Storage Batteries
Battery module
DCB-104E High-Rate battery module Unit for middle size application
Max. 15 modules in series.
Storage Batteries
Max. 15 modules in series 20 lines in parallel
7/5
7/6
7/7
7/8
7/11 7/14
Tue
Wed
Thu
Fri
Mon
20% 16%
11%
Storage Battery System
18% 20% 23%
The day in big result of PV July 15th, 2011 (FRI)
7/15 7/18 7/19 Fri 22%
7/20 7/21 7/22 7/25 7/26 7/28
Tue
Wed
Thu
19% 11%
18%
12%
Mon
Reduction by EMS PV Storage Discharge Consumed Electricity
8/1
8/2
8/3
Thu
Mon
Tue
Wed
18% 14% 18% 17%
17%
19% 20%
Fri
Mon Tue
The day in small result of PV July 19th, 2011 (TUE)
Average 17%
Reduction by EMS PV Storage Discharge Consumed Electricity
Peak cut
Peak cut
Battery module
DCB-104E
Peak hour of electricity demand (13 :00 ∼16 :00 )
High C-rate battery for high power application
0:00
9
Thu
6:00
12:00
18:00
Peak hour of electricity demand (13 :00 ∼16 :00 )
0:00
6:00
12:00
18:00
Storage Battery System
10
